ERJ Express. Published on August 9, 2012 as doi: 10.1183/09031936.00076912 Extracorporeal membrane oxygenation in a non intubated patient with acute respiratory distress syndrome (ARDS) Olaf Wiesner, * Johannes Hadem, * Wiebke Sommer, Christian Kühn, Tobias Welte, Marius M Hoeper Department of Respiratory Medicine (Olaf Wiesner MD, Tobias Welte, Marius M Hoeper MD), Department of Gastroenterology, Hepatology and Endocrinology (Johannes Hadem MD), and Department of Cardiovascular, Thoracic and Transplantation Surgery (Christian Kühn MD, Wiebke Sommer MD), all Hannover Medical School, Germany. *These authors contributed equally to the manuscript. Corresponding author: Marius M. Hoeper, Department of Respiratory Medicine, Hannover Medical School, Carl Neuberg Str. 1, 30625 Hannover, e mail: hoeper.marius@mh hannover.de Word count: 681 Copyright 2012 by the European Respiratory Society.
Endotracheal intubation and mechanical ventilation are mainstays in the management of patients with acute respiratory distress syndrome (ARDS), but this treatment strategy exposes the patient to several risks and complications. A small number of ARDS patients can be treated with noninvasive ventilation and these patients have less ventilator associated pneumonia and a lower mortality rate [1]. However, failure to improve oxygenation with noninvasive ventilation indicates the need for endotracheal intubation [1]. In patients with severe respiratory failure, extracorporeal membrane oxygenation (ECMO) is increasingly being used on top of mechanical ventilation to facilitate oxygenation and protective ventilation [2]. A novel concept is the use of ECMO in awake, spontaneously breathing patients to avoid the complications of invasive ventilation. So far, awake ECMO has been utilized predominantly in patients with end stage lung disease as bridge to lung transplantation [3, 4]. The use of awake ECMO as bridge to recovery has recently been described in a patient with hypercapnic respiratory failure [5], but not yet in patients with ARDS. We describe a patient with ARDS following septic shock who failed noninvasive ventilation and was successfully treated with awake ECMO, thereby avoiding endotracheal intubation and mechanical ventilation. This 26 year old female was admitted to our hospital with urosepsis caused by Escherichia coli. Past medical history was remarkable for Ewing s sarcoma, which had been treated with hemipelvectomy and radiochemotherapy 9 years ago and had been in remission since then. On admission, the patient presented with septic shock. Initial therapy consisted of volume resuscitation, intravenous norepinephrine, and antibiotics. At that time, the patient was mildly tachypneic but had clear lung fields on chest radiography and did not require supplemental oxygen therapy. On day 3, hemodynamics had stabilized and the patient no longer required vasopressors, but respiratory function progressively deteriorated. The patient became tachypneic and hypoxemic with increasing oxygen demand. Chest X ray now demonstrated disseminated patchy infiltrates in all lung fields. Noninvasive ventilation via a sealed facemask was instituted and an inspiratory oxygen fraction (FiO 2 ) of 0.7 was required to maintain oxygen saturations at 90%. After 9 hrs on noninvasive ventilation, the patient became agitated and oxygenation deteriorated (minute ventilation 17 l/min, FiO 2 0.7, po 2 50 mmhg, pco 2 36 mmhg). Her Murray score at that time was 3 (pao 2 /FiO 2 ratio 71; diffuse infiltrates in all 4 quadrants, continuous positive airway pressure 6 cmh 2 O on non invasive ventilation, lung compliance 23 ml/cmh 2 O) [6]. At that stage, the need for intubation was discussed with the patient who vehemently declined. Therefore, we suggested initiating awake veno venous ECMO support to which the patient agreed. Venous access was established via the left femoral and right internal jugular veins as described elsewhere [3]. The whole procedure was performed under local anesthesia and low dose analgosedation with 5 mg of morphine and 200 mg of propofol while patient was still responsive and receiving non invasive ventilation. Gas exchange improved immediately after ECMO insertion and the patient no longer required noninvasive ventilation. The patient felt comfortable (Figure 1), did not complain about dyspnea and did not require sedation any more. Details of the ECMO settings and the further clinical course are shown in Table 1. Gas
exchange subsequently improved and 4 days later, she was weaned from extracorporeal support. She fully recovered and was discharged from the hospital 8 days after decannulation. To best of our knowledge, this is the first report of awake ECMO in a patient with ARDS. Obviously, this strategy will not replace invasive ventilation as standard ARDS treatment, but it may become a viable alternative in carefully selected candidates. Our patient had already recovered from septic shock and was no longer in a hypotensive and hyperdynamic circulatory state, which was probably a prerequisite for the high efficacy of ECMO support. Her prompt improvement and rapid recovery after ECMO insertion were remarkable and the course of ARDS in patients receiving ECMO support without invasive ventilation warrants further study. In patients with more severe lung injury one might also consider the use of ECMO in awake patients receiving non invasive ventilation. To date, the use of ECMO in awake patients is investigational and must be carefully investigated before broader use.
Table 1: Patient s gas exchange and breathing patterns and ECMO settings Pre ECMO On ECMO Day 4 off ECMO Day 1 Day 2 Day 3 Respiratory Support NIV Nasal Nasal Nasal Nasal FiO 2 (%) 70 26 24 24 24 21 paco 2 (mmhg) 36 27 27 32 31 32 pao 2 (mmhg) 50 93 88 122 SpO 2 (%) 91 98 97 99 99 99 BR (breaths/min) 46 27 28 31 19 16 ECMO BF (L/min) 2.05 2.10 2.05 ECMO GF (L/min) 3 2 2 ECMO FiO 2 (%) 65 55 30 Day 5 Discharge from ICU None ECMO, extracorporeal membrane oxygenation; NIV, noninvasive ventilation; FiO 2 inspiratory oxygen fraction; PaCO 2,arterial carbon dioxide tension; PaO 2, arterial oxygentension; SpO 2, peripheral oxygen saturation; BR,breathing rate; BF, blood flow; GF, gas flow
Figure 1 Patient with ARDS treated with awake extracorporeal membrane oxygenation (ECMO). The patient is not intubated and breathing spontaneously. The ECMO device is located at the foot end of the bed. The ECMO cannulas are inserted in the left femoral vein and the right internal jugular vein.
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